Bead apex rubber-forming method, and bead apex rubber-forming device

ABSTRACT

The present invention forms bead apex rubber with good precision on the outer circumferential surface of the bead core. A molding process, in which unvulcanized rubber is made to flow into a bead apex molding chamber that is surrounded by surfaces that include the outer circumferential surface of a circular bead core and the bead apex rubber is formed directly on the outer circumferential surface of the bead core that is rotating around the core axis, is provided. The molding process comprises: a tip forming step that forms the leading end of the bead apex rubber; a middle section forming step that sequentially forms the bead apex rubber to be continuous with the leading end; and a joining step to join the back end and the leading end of the bead apex rubber by inflowing the unvulcanized rubber therebetween.

TECHNICAL FIELD

The present invention relates to a bead apex rubber forming method and a bead apex rubber-forming device capable of forming accurately bead apex rubber on an outer circumferential surface of a bead core.

BACKGROUND ART

As shown in FIG. 11(A) schematically, a bead portion (a) of a pneumatic tire is provided with an annular bead core (c) made of a hard steel wire and the like to fix both ends of the carcass (b) securely and to prevent from dropping-off of a rim. The radially outer circumferential surface of the bead core (c) is provided with bead apex rubber (d) having a triangle shape in cross-section to improve bead durability and steering stability and the like. This bead apex rubber (d) is gone into a tire manufacturing line as a bead apex rubber-core joint body jointed integrally with the bead core (c) in advance (hereinafter called a “core joint body”).

As the forming method of the core joint body, heretofore, as shown in FIG. 11(B), the bead apex rubber (d) having the triangle shape in cross-section extruded and formed with a rubber extruder is wrapped once on the outer circumferential surface of the bead core (c). Then both wrapping ends of tip portion and back-end portion are butted and jointed. At this time, the bead apex rubber (d) having a high temperature just after molding is soft and deformable. Therefore, to feed the bead apex rubber (d) just after molding to the bead core is not easy. It needs to once cool down after molding.

However, the cooling deteriorates adherence property of the bead apex rubber (d). In consequence, the lack of adhesion makes it easier to fall away the bead apex rubber (d) from the bead core (c) (see FIG. 12(A)). The cross-sectional shape deforms such as shrinking and curling of the bead apex rubber (d) in the width direction (see FIG. 12(B)). In the event of the severe curl, a tip portion (d1) and a back-end portion (d2) cannot be jointed. when the cross-sectional height of the bead apex rubber (d) is large, the bead apex rubber (d) falls due to the curl and it makes difficult to form the core joint body. Also there is problems that the joint portion drops off between the tip portion (d1) and the back-end portion (d2) owing to adhesion insufficiency (see FIG. 12(C)), and a gap (f) between the tip portion (d1) and the back-end portion (d2) (see FIG. 12(D)) and overlapping (g) between the tip portion (d1) and the back-end portion (d2) (see FIG. 12(E)) causes weight unbalance.

As a conventional device of the bead apex rubber to the bead core is known as the following Patent Documents 1 and 2.

BACKGROUND OF THE INVENTION Patent Documents

-   Patent Document 1: Japanese Unexamined Patent Application     Publication No. H10-291261 -   Patent Document 1: Japanese Unexamined Patent Application     Publication No. 2004-202960

GENERAL DESCRIPTION OF THE INVENTION Problems to be Resolved by the Invention

It is an object of the present invention to provide the bead apex rubber forming method and a bead apex rubber-forming device capable of keeping a high adhesion strength between the bead apex rubber and the bead core, and of preventing the deformation caused by the shrinking; moreover, the bead apex rubber is substantially formed in a joint-less form, the problems of the weight unbalance caused by the occurrence of the gap and overlapping in the joint portion and the adhesion dropping-off in joint portion can be prevented.

Means of Solving the Problems

In the invention according to claim 1, a bead apex rubber forming method forms the bead apex rubber continuously in a full circle on an outer circumferential surface of the annular bead core having a core axis. the method comprises a molding process to form the bead apex rubber integrally on the outer circumferential surface of the bead core rotating around the core axis by flowing unvulcanized rubber from a rubber inflow port positioned in a first inner wall surface of a molding head into a bead apex molding chamber. The bead apex molding chamber is surrounded by the outer circumferential surface of the bead core, a first inner wall surface of the molding head on one side of the core axis direction, and a second inner wall surface of the molding head on the other side of the core axis direction. The bead apex molding chamber extends in the circumferential direction, and of which circumferential both ends are opened. The molding process comprises a tip forming step, a middle section forming step and a joining step. The tip forming step forms a tip portion of the bead apex rubber between front and rear shutters by flowing the unvulcanized rubber into the bead apex molding chamber, in a closed state that the bead apex molding chamber is closed by the front and rear shutters on the front and rear sides in the bead core rotating direction in relation to the rubber inflow port, and in a rotating stopped state of the bead core. The middle section forming step forms serially the bead apex rubber to be continuous with the tip portion by taking off the front shutter to open the front side in the bead core rotational direction and flowing the unvulcanized rubber while rotating the bead core. The joining step joints integrally the back-end portion and the tip portion by a rubber connecting portion. In the joining step, the bead core is stopped when the tip portion returns again to the bead apex molding chamber, the rear shutter is taken off to open the rear side in the bead core rotational direction and to form a connecting space between the back-end portion and the tip portion of the bead apex rubber, and the unvulcanized rubber is flowed into the connecting space to form the rubber connecting portion.

In the invention according to claim 2, a bead apex rubber forming device forms the bead apex rubber continuously in a full circle on an outer circumferential surface of the annular bead core having a core axis. The bead apex rubber forming device comprises a bead core holding means for holding the bead core rotatably around the core axis, a rubber extruder having a gear pump for extruding the unvulcanized rubber from a rubber discharge port depending on an on-off action of the gear pump, and a molding head fixed to the anterior end of the rubber extruder. The molding head comprises a passing space where a part of the rotating bead core passes. The passing space comprises a bead apex molding chamber surrounded by the outer circumferential surface of the bead core passing the passing space, a first inner wall surface of the molding head on one side of the core axis direction, and a second inner wall surface of the molding head on the other side of the core axis direction. The bead apex molding chamber extends in the circumferential direction, and of which circumferential both ends are opened. The first inner wall surface is provided with a rubber inflow port connected with the rubber discharge port via a rubber flow channel to flow the unvulcanized rubber from the rubber extruder into the bead apex molding chamber. The molding head comprises the front shutter, the rear shutter and a cutter. The front shutter closes the bead apex molding chamber on the front side in the bead core rotational direction in relation to the rubber inflow port. The rear shutter closes the bead apex molding chamber on the rear side in the bead core rotational direction in relation to the rubber inflow port. The cutter cuts the rubber portion in the rubber flow channel from the rubber portion in the bead apex molding chamber by crossing the rubber inflow port along the first inner wall surface.

Effect of the Invention

A bead apex rubber forming method comprises a molding process to form a bead apex rubber, by flowing unvulcanized rubber into a bead apex molding chamber, directly on an outer circumferential surface of a bead core rotating around a core axis. This molding process comprises a tip forming step to form a tip portion of the bead apex rubber, a middle section forming step to form serially the bead apex rubber to be continuous with the tip portion, and a joining step to joint a back-end portion and the tip portion by flowing unvulcanized rubber.

In the tip forming step, front and rear shutters close the bead apex molding chamber on the front side and rear side in the bead core rotational direction in related to the rubber inflow port. And, in a rotating stopped state of the bead core, the unvulcanized rubber is flowed into the closed bead apex molding chamber so as to form the tip portion of the bead apex rubber.

Firstly, in the tip forming step, since the bead apex molding chamber is in the closed state, the rubber inner pressure can be heightened in the molding chamber. Therefore, owing to the rubber filled up in the molding chamber, the tip portion can be accurately made. Since the rubber inner pressure is high, the sticking force between the tip portion and the bead core is heightened, adhesion strength can be improved.

Secondly, in the middle section forming step, in a state that the front side in the bead core rotational direction is opened by taking off the front shutter, the unvulcanized rubber flows while the bead core rotating. This makes the bead apex rubber serially to be continuous with the tip portion.

In the bead apex molding chamber, since the tip portion has al ready been formed, when also the front shutter is taken off, the bead apex molding chamber is substantially in the closed state. Therefore, the rubber flowed from the rubber inflow port pushes the rubber molding portion, which has already molded in the bead apex molding chamber, toward the front side in the bead core rotational direction, and connecting with the rubber molding portion. At this time, the bead core can integrally rotates with the rubber molding portion owing to the pushing force by the rubber toward the front side in the bead core rotational direction.

Finally, in the joining step, the bead core rotates substantially once, and the tip portion come back to the bead apex molding chamber, the bead core is stopped, and the rear shutter is removed to open the rear side in the bead core rotational direction. This forms a connecting space between a back-end portion and the tip portion of the bead apex rubber. And in the connecting space, the unvulcanized rubber is flowed more. This allows integrally connect the back-end portion and the tip portion by the rubber connecting portion.

As seen from the above, the space between the tip portion and the back-end portion is filled with the flowed unvulcanized rubber and connected in the same cross-section shape, and the bead apex rubber gets to have a substantially joint-less structure. Therefore, the conventional gap and overlapping attributed to a joint do not occur, weight dispersion is inhibited, and adhesive separation in the joint portion can be prevented.

Furthermore, the bead apex rubber is formed in a circular form in holding a high-temperature state. Thus, the shrinking and a deformation attributed to the shrinking can be inhibited by constriction in whole. And, since the bead apex rubber is integrally formed with the bead core, the bead apex rubber and the bead core can keep high adhesion strength.

And, it eliminates the need for a conventional cooling process and a pasting process. Therefore, this can make a contribution by reducing number of processes, improving production efficiency, reducing factory space, and downsizing a manufacturing line and an apparatus.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 A side view showing an embodiment of a bead apex rubber forming device for a bead apex rubber forming method of the present invention.

FIG. 2 A side enlarged view of a major portion of the bead apex rubber forming device.

FIG. 3 A perspective view of the major portion of the bead apex rubber forming device.

FIG. 4 A cross-sectional overhead view of the major portion of the bead apex rubber forming device.

FIG. 5 A perspective view showing a bead core holding means.

FIG. 6(A) is a cross-sectional view of a bead apex molding chamber in the core axis direction, and (B) is an exploded perspective view thereof.

FIG. 7 A front view conceptually showing a molding process.

FIG. 8 A cross-sectional overhead view explaining a tip forming step.

FIG. 9 A cross-sectional overhead view explaining a middle section forming step.

FIG. 10 A cross-sectional overhead view explaining a joining step.

FIG. 11(A) is a cross-sectional view of a bead portion of a tire, and (B) is a side view of a conventional forming method of a bead apex rubber.

FIG. 12(A) to (E) are drawings showing some problems of the conventional bead apex rubber forming method.

MODE FOR CARRYING OUT THE INVENTION

Hereinafter, preferred embodiments of the present invention will be concretely described. FIG. 1 is a side view showing an embodiment of a bead apex rubber forming device 1 (may be simply called “forming device 1”).

As shown in FIG. 1, the forming device 1 comprises a bead core holding means 2 for holding rotatably an annular bead core A around a core axis, a rubber extruder 4 extruding unvulcanized rubber G from a rubber discharge port 3, and a molding head 5 fixed to a anterior end of the rubber extruder 4. As shown in FIG. 3, the forming device 1 forms a bead apex rubber B in a full circle on the outer circumferential surface of the bead core A.

In the present embodiment, as shown in FIG. 5, the bead core holding means 2 comprises a pair of parallel holding rollers 2 a, 2 a to hold an inner periphery of the bead core A. The holding rollers 2 a, 2 a is rotatably mounted on a supporting platform 6 (shown in FIGS. 1 and 2) holding the molding head 5 via a roller holder 7. The bead core A is rotatably held around the horizontal core axis in suspending and straddled state between the holding rollers 2 a, 2 a. The bead core holding means 2 of the present embodiment comprises plural of side rollers 2 b to keep a posture stability of the bead core A by holding a side surface of the bead core A.

The rubber extruder 4 is provided in the anterior end portion with a gear pump 8, and extrudes the unvulcanized rubber G from a rubber discharge port 9 (shown in FIG. 4) depending on an on-off action of the gear pump 8. Specifically, the rubber extruder 4 of the present embodiment comprises a rubber extruder main body 10 pushing the input rubber G toward a opening 10H of the anterior end while kneading, and the gear pump 8 provided with the anterior end portion of the rubber extruder main body 10. The rubber extruder main body 10 has a well-known structure comprising a cylinder 10 a comprising the rubber slot 10 c and a screw shaft 10 b disposed in the cylinder 10 a. Owing to the rotation of the screw shaft 10 b by the electric motor M, the rubber G is extruded with kneading from the opening 10H of the anterior end of cylinder 10 a.

As shown in FIG. 2, the gear pump 8 is a well-known isovolumic extruder. The gear pump 8 comprises a case 11 and a pair of extrusion gears 8 a disposed in the case 11. The extrusion gears 8 a rotate in engaging one another with an electric motor (not shown). And the rubber G extruded from the rubber extruder main body 10 is pushed from the rubber discharge port 9 (shown in FIG. 4) of the anterior end. The case 11 of the present embodiment is attached to the anterior end of the rubber extruder main body 10 and supported from underneath by the supporting platform 6.

As shown FIGS. 2, 6(A), and 6(B), the molding head 5 comprises a passing space 12 where a part of the rotating bead core A passes in the circumferential direction. The passing space 12 comprises a bead apex molding chamber 15 (may be simply called “molding chamber 15”) having a triangle-shaped in cross-sectional view. The molding chamber 15 is surrounded by the outer circumferential surface As of the bead core A passing through the passing space 12, a first inner wall surface 13 s of the molding head 5 on one side of the core axis direction, and a second inner wall surface 14 s of the molding head 5 on the other side. The molding chamber 15 extends in the circumferential direction, and the both end portions thereof are open.

Specifically, the molding head 5 of the present embodiment comprises a head main body 13 fixed on the side of the gear pump 8, and a cover plate 14 kept on the head main body 13 with a holding means 17. An exterior surface 13A of the head main body 13 forms the first inner wall surface 13 s of the molding chamber 15. An internal face 14A of the cover plate 14 forms the second inner wall surface 14 s of the molding chamber 15. Technically, the internal face 14A of the cover plate 14 of the present embodiment comprises a contacting surface 14A1 positioned on the exterior surface 13A of the head main body 13, and a sloping surface 14A2 continuing into the contacting surface 14A1. And the sloping surface 14A2 forms the second inner wall surface 14 s. The cover plate 14 can change its positions between a closed state Y1 for forming the molding chamber 15 and an opened state Y2 for opening the molding chamber 15 by the holding means 17 such as using cylinder. In the opened state Y2, a takeoff of the core assembled body from the molding chamber 15 and a mounting of a next bead core A onto the molding chamber 15 are conducted.

In the first inner wall surface 13 s of the molding head 5, a rubber inflow port 19 opens. As shown in FIGS. 4 and 8, the rubber inflow port 19 continues into the rubber discharge port 9 via a rubber flow channel 18 and let flow the rubber G input from the rubber extruder 4 into the molding chamber 15. The rubber flow channel 18 comprises a tapered squeezing channel 18 a having a cross-sectional area gradually reduced toward the front, and a parallel channel 18 b extending from the squeezing channel 18 a to the rubber inflow port 19 and having a substantially constant cross-sectional area. The parallel channel 18 b inclines to the front side F1 in the bead core rotational direction.

The molding head 5 comprises a front shutter 20 to close the molding chamber 15 on the front side F1 in the bead core rotational direction in relation to the rubber inflow port 19, a rear shutter 21 to close the molding chamber 15 on the rear side F2 in the bead core rotational direction in relation to the rubber inflow port 19. In the present embodiment, in a circumferential front of the molding head 5, a guiding grove 22 extends up and down. The front shutter 20 is movable up and down along the guiding groove 22. Therefore the molding chamber 15 can be opened and closed the front side F1 in the bead core rotational direction in relation to the rubber inflow port 19.

The head main body 13 comprises a guiding groove 23 extending at an angle toward the front side F1 in the bead core rotational direction and intersecting with the molding chamber 15. The rear shutter 21 is movable back and forth along the guiding groove 23. In a forward movement, the rear shutter 21 traverses the molding chamber 15, and its anterior end surface 21 s thickly contacts with the second inner wall surface 14 s. Thus the rear shutter 21 can close the molding chamber 15 the rear side F2 in the bead core rotational direction in relation to the rubber inflow port 19. In the posterior movement of the rear shutter 21, the molding chamber 15 is opened. It is preferable to open-and-close the rear shutter 21 at a position near the rubber inflow port 19 in a joining step described below for letting flow the unvulcanized rubber G into a connecting space J. Therefore, a distance L (shown in FIG. 8) between the guiding groove 23 and the rubber inflow port 19 is set to be not more than 1 mm. For the same purpose, an angle θ1 of the guiding groove 23 with respect to the circumferential direction is also preferably set to be smaller than an angle θ2 of the parallel channel 18 b with respect to the circumferential direction.

The molding head 5 comprises a cutter 25. The cutter 25 cuts across the rubber inflow port 19 along the first inner wall surface 13 s. And the cutter 25 cuts off the rubber in the rubber flow channel 18 from the rubber in the molding chamber 15. The cutter 25 of the present embodiment can move back and forth along the guiding groove 26 formed in the first inner wall surface 13 s. The rubber inflow port 19 opens in a bottom face of the guiding groove 26. Meanwhile an item 30 shown in FIG. 4 indicates a driving means for driving the cutter 25, and a cylinder is employed in the present embodiment. An item 31 indicates a driving means of the rear shutter 21, and a gear-rack structure is employed in the present embodiment. The front shutter 20 is derived by a driving means (not shown) such as the cylinder.

Next, a bead apex rubber forming method (may be simply called “forming method”) will be explained with the forming device 1.

As shown in FIG. 7, the forming method of the present embodiment comprises a molding process P to form the bead apex rubber B integrally on an outer circumferential surface As of a rotating bead core A by letting flow the unvulcanized rubber G from the rubber inflow port 19 into the molding chamber 15.

The molding process P, as shown in FIG. 7, comprises a tip forming step P1 to form a tip portion Bf of the bead apex rubber B, a middle section forming step P2 to form serially the bead apex rubber B so as to be continuous with the tip portion Bf, and a joining step P3 to connect integrally the back-end portion Br with the tip portion Bf by flowing the unvulcanized rubber in the connecting space J between the back-end portion Br and the tip portion Bf.

FIGS. 8 to 10 are overhead views of the molding chamber 15, the bead core A is abbreviated for convenience sake. As shown in FIG. 8, in the tip forming step P1, the front and rear shutters 20, 21 close the molding chamber 15 on the front side F1 and the rear side F2 in the bead core rotational direction in relation to the rubber inflow port 19. In a rotating stopped state of the bead core A, the molding chamber 15 in the closed state is filled with the poured unvulcanized rubber G. Thus the tip portion Bf of the bead apex rubber B is formed between the front and rear shutters 20, 21.

In this time, the molding chamber 15 gets into the closed state by the front and rear shutters 20, 21, a rubber inner pressure can be raised in the molding chamber 15. In consequence, the tip portion Bf can be formed accurately. And since the rubber inner pressure is high, the sticking force between the tip portion Bf and the bead core A is heightened, and the adhesion strength can be improved. Meanwhile, the inflow-and-stop and the volume of flow of the rubber G is controlled with the on-and-off of the gear pump 8.

As shown in FIG. 9, in the middle section forming step P2, the front shutter 20 is taken off, and the front side F1 in the bead core rotational direction is opened, and the unvulcanized rubber G is flowed from the rubber inflow port 19 while rotating the bead core A. This connects with the tip portion Bf to form the bead apex rubber B serially.

In the molding chamber 15, since the tip portion Bf has already been formed, even if the front shutter 20 is taken off, the molding chamber 15 is substantially in the closed state. Therefore, the rubber G flowed from the rubber inflow port 19 pushes the rubber molding portion, which has been already formed in the molding chamber 15, toward the front side F1 in the bead core rotational direction and connects with the rubber molding portion to form the bead apex rubber B serially. At this time, the bead core A can integrally rotates with the rubber molding portion owing to the pushing force by the rubber G toward the front side F1 in the bead core rotational direction. That is to say, the forming device 1 of the present embodiment needs no motor and the like to drive the bead core A, but the pushing force of the rubber G rotates automatically. Therefore, the structure of the bead core holding means 2 can be simplified.

In the joining step P3, when the bead core A substantially goes around and the tip portion Bf comes back to the molding chamber 15, the rotation of the bead core A gets stopped (FIG. 10(A)). This stopping can be conducted with the stop of flowing of the rubber G from the rubber inflow port 19 by the gear pump 8. And, supplementary, brake means can be employed. Subsequently, the rear shutter 21 sets back to open the rear side F2 in the bead core rotational direction (FIG. 10(B)). This forms a connecting space J between the back-end portion Br and the tip portion Bf of the bead apex rubber B. In the present embodiment, since a backward amount of the rear shutter 21 is large, the cutter 25 is carried forward the position of the back-end portion Br so as to the cutter 25 forms a first inner wall surface 13 s in the connecting space J (FIG. 10(C)). However, the first inner wall surface 13 s in the connecting space J can be also made by carry backward the anterior end surface 21 s of the rear shutter 21 to the same plane of the first inner wall surface 13 s.

After forming the connecting space J, by putting the gear pump 8 into practice, the rubber G can be flowed into the connecting space J. The back-end portion Br and the tip portion Bf are integrally connected by the rubber connecting portion Bm (FIG. 10(D)). Since the rubber inflow port 19 is positioned near the rear shutter 21, and since the rear shutter 21 inclines toward the front side F1 in the bead core rotational direction, in the back-end portion Br, the connecting side with the rubber inflow port 19 takes the form of having an acute angle. Therefore, the rubber G from the rubber inflow port 19 can flow easily from the acute angle part into the connecting space J.

In the present embodiment, after forming the rubber connecting portion Bm, a cutoff step P4 is conducted (FIG. 10(E)). In the cutoff step P4, the cutter 25 carries forward to across the rubber inflow port 19 along the first inner wall surface 13 s. In doing so, the bead apex rubber B is cut off from the rubber portion in the rubber flow channel 18. The rubber inflow port 19 has a small diameter. Therefore, the rubber can be cut off not using the cutter 25 but strain at the time of taking the core assembled body off from the molding chamber 15.

As presented above, in the molding process P, the tip portion Bf and the back-end portion Br can also connected in the same cross-sectional shape with the flow of the unvulcanized rubber. Thus, the bead apex rubber B is formed in a substantially joint-less form. Therefore, the conventional gap and overlapping attributed to a joint do not occur, the weight dispersion is inhibited, and adhesive separation in the joint portion can be prevented.

Although the especially preferred embodiments of the present invention have been described in detail, the invention is not limited to the above-mentioned specific embodiments, and various modifications can be made.

EXPLANATION OF THE REFERENCE

-   1 Bead apex rubber forming device -   2 Bead core holding means -   3 Rubber discharge port -   4 Rubber extruder -   5 Molding head -   8 Gear pump -   12 Passing space -   13 s First inner wall surface -   14 s Second inner wall surface -   15 Bead apex molding chamber -   18 Rubber flow channel -   19 Rubber inflow port -   20 Front shutter -   21 Rear shutter -   25 Cutter -   A Bead core -   As Outer circumferential surface -   B Bead apex rubber -   Bf Tip portion -   Bm Rubber connecting portion -   Br Back-end portion -   G Unvulcanized rubber -   J Connecting space -   P Molding process -   P1 Tip forming step -   P2 Middle section forming step -   P3 Joining step 

The invention claimed is:
 1. A bead apex rubber forming method to form the bead apex rubber continuously in a full circle on an outer circumferential surface of an annular bead core having a core axis, wherein the method comprises a molding process to form the bead apex rubber integrally on the outer circumferential surface of the bead core while it rotates around the core axis by flowing unvulcanized rubber from a rubber inflow port positioned in a first inner wall surface of a molding head into a bead apex molding chamber, the bead apex molding chamber is surrounded by the outer circumferential surface of the bead core, the first inner wall surface of the molding head on one side of the core axis direction, and a second inner wall surface of the molding head on the other side of the core axis direction, and wherein the bead apex molding chamber extends in the circumferential direction of the circumferential surface, and the bead apex molding chamber is openable and closable in the circumferential direction by front and rear shutters on a front portion and a rear portion respectively of the bead apex molding chamber in the bead core rotating direction in relation to the rubber inflow port, wherein the molding process comprises a tip forming step to form a tip portion of the bead apex rubber between the front and rear shutters by flowing the unvulcanized rubber into the bead apex molding chamber, in a closed state in which the bead apex molding chamber is closed by the front and rear shutters, and in a state in which the rotation of the bead core is prevented, a middle section forming step progressively forming the bead apex rubber to be continuous with the tip portion by taking away the front shutter from the bead apex molding chamber and flowing the unvulcanized rubber while rotating the bead core, a joining step to joint integrally a rear end of the bead apex rubber positioned at the bead apex molding chamber and the tip portion by a rubber connecting portion, and a cut-off step to cut the bead apex rubber off from the rubber in a rubber flow channel which feeds rubber to the rubber inflow port by moving a cutter across the rubber inflow port along the first inner wall surface, wherein the rear shutter is positioned between a rear end of the bead apex molding chamber corresponding to an upstream side of the chamber with respect to the bead core rotating direction and the rubber inflow port, so that a space in the chamber for the tip of the bead apex rubber to enter into is formed in the bead apex molding chamber and between the rear end of the bead apex molding chamber and the rear shutter, and in the joining step, the bead core is stopped when the tip portion returns into said space of the bead apex molding chamber between the rear end of the bead apex molding chamber and the rear shutter, the rear shutter is taken away from the bead apex molding chamber to form a connecting space between the rear end of the bead apex rubber and the tip portion of the bead apex rubber, and the unvulcanized rubber is flowed into the connecting space to form the rubber connecting portion, wherein, the cutter is slidable along a cutter-guiding groove formed on the first inner wall surface, the rear shutter is slidable along a shutter-guiding groove of the molding head, the rubber inflow port and the shutter-guiding groove open in a bottom-surface of the cutter-guiding groove that is opposite to the bead apex molding chamber in a thickness direction of the cutter-guiding groove, and the opening of the rubber inflow port and the opening of the shutter-guiding groove are arranged side by side in the circumferential direction.
 2. The bead apex rubber forming method as set forth in claim 1, wherein the shutter-guiding groove is inclined at an angle toward a front end of the bead apex molding chamber in the bead core rotating direction.
 3. The bead apex rubber forming method as set forth in claim 1, wherein a distance along the first inner wall surface between the opening of the shutter-guiding groove and the opening of the rubber inflow port is not more than 1 mm.
 4. The bead apex rubber forming method as set forth in claim 1, wherein an angle of the shutter-guiding groove with respect to the circumferential direction is smaller than an angle of the rubber flow channel with respect to the circumferential direction.
 5. The bead apex rubber forming method as set forth in claim 1, wherein, in the joining step, the unvulcanized rubber is flowed into the connecting space in a state where the cutter closes the opening of the shutter-guiding groove.
 6. The bead apex rubber forming method as set forth in claim 1, wherein, in the joining step, the unvulcanized rubber is flowed into the connecting space in a state where the anterior end surface of the rear shutter is flush with the bottom-surface of the cutter-guiding groove. 